Light emitting device

ABSTRACT

A light emitting device is described. The light emitting device includes a base; a light emitting diode supported by the base; a first layer spaced apart from the light emitting diode and including a light emitting material, the first layer having a refractive index n first     —     layer ; a transparent optic having a refractive index n optic  that is greater than or equal to n first     —     layer , the transparent optic having a convex surface facing away from the light emitting diode and the first layer being positioned between the transparent optic and the light emitting diode. A gap between the light emitting diode and the first layer has a refractive index n gap  that is less than n first     —     layer , and the convex surface has a radius of curvature sufficiently large relative to a dimension of the first layer to eliminate total internal reflection of light entering the transparent optic from the first layer.

RELATED APPLICATION

This application is a continuation application related to and claiming the benefit of U.S. patent application Ser. No. 12/669,597, filed Jun. 28, 2010, which is a 371 of international PCT/US2008/070621, filed Jul. 21, 2008, which, in turn, is a non provisional application of U.S. Provisional Application No. 60/961,185, filed Jul. 19, 2007, the disclosures of which are incorporated herein by reference.

TECHNICAL FIELD

The present invention relates generally to the field of solid-state lighting and more specifically to high efficiency phosphor-converted LEDs.

BACKGROUND

Solid-state lighting (SSL) is a type of lighting that does not use an electrical filament or a gas in the production of light. A primary advantage of SSL over conventional lighting technologies is the potential energy savings as a result of its higher luminous efficiencies over conventional lighting devices. For example, SSL is capable of 50% efficiency with 200 lumen per watt (lm/W) efficacy (compared to 15 lm/W for incandescents and 60-90 lm/W for fluorescents) and up 100 khr lifetimes. This is approximately 100 times the lifetime of conventional incandescent bulbs and 10 times the lifetime of fluorescents. The Department of Energy (DOE) has set a goal of 50% electrical-to-optical system efficiency with a spectrum accurately reproducing the solar spectrum by 2020. The Optoelectronic Industry Development Association (OIDA) aims for 200-lm/W luminous efficiency with a color rendering index, greater than 80.

Each of these conventional methods and devices has deficiencies. Color mixing is hindered by the absence of an efficient LED material in the 500 nm to 580 mm (green-to-yellow) range. Wavelength conversion suffers from phosphor conversion loss and package designs that do not extract phosphor-converted light efficiently.

SSL devices primarily include light emitting diodes (LEDs), which include a small chip semiconductor, i.e. the LED source, mounted in a reflector cup on a lead frame. The LED source generates photons of light at a first wavelength when energized. The reflector cup reflects photons out of the LED. An optic, generally a silicone or epoxy encapsulation, aids in light extraction from the LED source and protects the LED components.

High efficiency generation of white light with LEDs has conventionally been according to one of three methods: 1) color mixing; 2) wavelength conversion; or 3) a combination of methods 1 and 2. Color mixing is the use of multiple LEDs across the visible spectrum (e.g. blue+green+red LEDs), which combine to produce a white light. Wavelength conversion is the use of a single, efficient, short wavelength LED emitting light at the first wavelength, which is then at least partially absorbed by a phosphor within the LED and re-emitted at a second wavelength. LEDs under method 2 are generally referred to as phosphor-converted LEDs (pcLEDs).

Conventional pcLEDs have generally two structural arrangements. First, the phosphor can encompass the LED source of the LED. The phosphor is typically a YAG:Ce crystalline powder in direct contact with the blue wavelength emitting LED source. Both are positioned upon a heat sink base and surrounded by an optic. The other arrangement is a scattered photon extraction (SPE) pcLED, which positions a planar phosphor-layer at a distance away from the LED source. Herein, the YAG:Ce phosphor, in powder form, creates a diffuse, semitransparent layer upon an acrylic optic with a planar surface.

When the phosphor is in direct contact with the LED source, the phosphor suffers from optical losses by reflection of phosphor-emission back into the LED source rather than through the optic and out of the LED. This can account for up to 60% of the total phosphor emission. The SPE pcLED suffers from scattering of the phosphor emissions. Scattering is the result of substantial differences in the indices of refraction of the phosphor powder and the material that encapsulates the phosphor (air, silicon, PMMA, or glass). The index of refraction, n, is a measure of the relative speed of light in a medium as compared to in a vacuum (where n_(vac)=1). When light passes from one medium to another medium with a substantially different index of refraction, the speed and direction of the light changes and is known as refraction. Refraction can lead to a randomization, or scattering, of the directionality of the light. Scattering then reduces efficiency by increasing the path length (a) inside the phosphor layer by trapping of the emissions by total internal reflection and (b) inside the device package because of random directionality of the phosphor emission, both of which can lead to reabsorption and optical loss.

These phosphor-related deficiencies are then compounded by secondary losses encountered by other package design deficiencies, such as imperfections of the reflector cup within the LED. While the reflector cup is intended to direct the phosphor-emission out of the LED, internal reflections and path randomization can trap a portion of the phosphor-emission, such as between the reflector cup and the phosphor, and decrease LED efficiency by approximately 30%.

Thus, to reach the efficiency goals set forth by the DOE, the problems associated with package design must be eliminated by designing a high efficiency LED that resolves the issues identified above.

SUMMARY OF THE INVENTION

According to the embodiments of the present invention, a light emitting composite material is described. The light emitting composite material includes a glassy material and a plurality of phosphor particles suspended within the glassy material, wherein the refractive index of the plurality of phosphor particles is approximately equal to the refractive index of the glassy material.

The plurality of phosphor particles can be composed of an inorganic crystalline material selected from the group consisting of Y_(x)Gd_(y)Al_(v)Ga_(w)O₁₂:M³⁺, wherein x+y=3 and v+w=5; SrGa₂S₄:M²⁺; SrS:M²⁺; X₂Si₅N₈:M²⁺; and XSi₂O₂N₂:M²⁺, wherein X is selected from the group consisting of Be, Mg, Ca, Sr, and Ba and wherein M is selected from a group consisting of Ce, Eu, Mn, Nd, Pr, Sm, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Sc, Ti, V, Cr, Fe, Co, Ni, Cu, Zn, Ir, and Pt.

The glassy material can be an optical glass comprising an amount from 5% to about 35% of SiO₂; an amount from about 55% to about 88% of PbO; optionally an amount less than 10% B₂O₃; optionally a combined amount less than 8% of Na₂O and K₂O; and optionally a combined amount less than about 15% total of TiO₂, ZrO₂, La₂O₃, ZnO, and BaO.

In other light emitting composites, the glassy material can be an optical glass comprising an amount from about 21% to about 30% of TiO₂; an amount from about 30% to about 50% of BaO, NaO, BeO, CaO, SrO, CdO, Ga₂O₃, In₂O₃, or Y₂O₃; an amount from about 18% to about 24% of Al₂O₃; and an amount from about 1% to about 10% of SiO₂, B₂O₃, PbO, GeO₂, SnO₂, ZrO₂, HfO₂, or ThO₂.

In another aspect of the present invention, the light emitting composites of the present invention can be used within a phosphor-containing light emitting device (pcLED). The pcLED can be constructed as an Enhanced Light Extraction by Internal Reflection (ELIXIR) LED device.

In yet another aspect of the present invention, the light emitting composite can be used with a solid-state laser.

In yet another aspect of the present invention, the light emitting composite can be used as a luminescence collector.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a diagrammatic cross-sectional view of the ELIXIR LED device according an embodiment of the present invention.

FIG. 2 is a sample spectrum demonstrating the LED source emission band, the phosphor absorption band, and the phosphor emission band.

FIG. 3 is a diagrammatic cross-sectional view of the ELIXIR LED device according to another embodiment of the present invention.

FIG. 4 is an enlarged diagrammatic cross-sectional view of a nearly-indexed matched luminescent glass crystal composite.

FIG. 5A is a diagrammatic cross-sectional view of the total internal reflections within a conventional pcLED device.

FIG. 5B is a diagrammatic cross-sectional view that illustrates the relation between the relative radii of first and second materials, which leads to total internal reflection.

FIG. 6 is a diagrammatic view of a conventional pumped solid-state laser device.

FIG. 7 is a diagrammatic view of a pumped solid-state laser device according to an embodiment of the present invention.

FIG. 8 is a diagrammatic view of a luminescence collector according to an embodiment of the present invention.

FIG. 9 is a diagrammatic cross-sectional view of the result of a ray trace diagram for the ELIXIR LED device according to one embodiment of the present invention.

DETAILED DESCRIPTION

Efficiency of a fully wavelength converted pcLED can be expressed as η_(pcL)=η_(LED)·η_(s)·η_(q)·η_(p)  Equation 1 where η_(pcL) is the total pcLED efficiency and is dependent upon the efficiency of the particular LED source, η_(LED); the Stokes conversion efficiency, η_(s), which is the quantum ratio of the average emission wavelengths of the LED and the phosphor; the phosphor quantum efficiency, η_(q), which indicates the efficiency of the quantum conversion of light from a first wavelength to a second wavelength inside the phosphor; and the package efficiency, η_(p), which is the efficiency of light extraction of LED- and phosphor-emitted photons from the LED device package. The product of η_(q)·η_(p) is the conversion efficiency (CE) for an LED device. The embodiments of the present invention optimize CE.

Package efficiency, η_(p), of the present invention is improved over conventional LED devices by first separating an LED source 12 from first and second non-planar layers, wherein the second layer is composed of a phosphor 14, which will nearly eliminate the reflection of phosphor- and LED-emissions back into the LED source 12. Secondly, a planar reflector 16 is used to reduce the number of mirror reflections over the conventional LED. The result is an Enhanced Light eXtraction by Internal Reflection (ELIXIR) LED device 10, shown in FIG. 1.

The ELIXIR LED 10 more specifically includes the first non-planar layer, i.e. a glass cover 18, surrounding and making immediate contact with the second non-planar layer, i.e. a phosphor 14, and a LED source 12 upon a heat sink base 20. The phosphor 14 and the LED source 12 are separated by a radius sufficient to substantially reduce the likelihood of phosphor-emissions reentering the LED source 12. This distance, r, is dependent upon a specified fraction of reentry, P, and is given by: r≧√[A/(4·π·P)]  Equation 2 Herein, A is the size of the LED source 12, i.e. the surface area of the LED chip. The high package efficiency is maintained as long as the proportions of the ELIXIR LED 10, namely the r_(phosphor)/r_(optic) ratio, are preserved, as described below in connection with FIG. 5B. The ELIXIR LED 10 size is ultimately limited by the size of the LED source 12. The distance to the phosphor 14 from the LED source 12 must be sufficiently long so that only a small fraction of converted light re-enters the LED source 12, where high losses occur. For example, a typical power LED chip has an area of ˜1 mm². If we specify that less than 1% of phosphor light emitted from any point on the phosphor 14 may reenter the LED source 12, a minimum LED source 12 to phosphor 14 separation of approximately √1 mm²/(4π(0.01)), or ˜2.8 mm is obtained. The minimum ELIXIR LED 10 diameter would be four times this value, ˜1.1 cm, which is approaching the size of the transparent lens encapsulation and smaller than the heat sink diameter on a typical power LED.

The LED source 12 can include any conventional resonance cavity LED or laser diode source generally emitting a light having a first wavelength ranging between about 350 nm to about 500 nm. This can include, but should not be limited to, a blue power LED with a peak wavelength of 455 nm with a 1000 mA DC drive capability.

The glass cover 18 can be any material suitable for the lens construction and for protection of the phosphor 14 and LED source 12, such as polymethyl methacrylate (PMMA), silicones, and glasses. In an alternative embodiment described herein, the glass cover 18 and the phosphor 14 may be made integral.

The phosphor 14 is applied to the glass cover 18 as a layer of inorganic phosphor crystalline powder. The phosphor 14 can be applied as a layer, for example, of about 100 μm in thickness, to an inner surface of the glass cover 18 from a solution of acetone or other solvent. The phosphor 14 should be selected such that the phosphor absorption band substantially overlaps with the LED-emission band, as shown in FIG. 2. This ensures efficient transfer from the first wavelength, the LED-emission, to the second wavelength, the phosphor-emission. Thus, a suitable phosphor for use with the blue power LED source can be Johnson Polymer Joncryl 587 modified styrene acrylic with 0.2% BASF Lumogen F Yellow 083 fluorescent dye.

Though not specifically shown, the glass cover 18 can be eliminated and the phosphor 14 is applied as a layer upon the inside radius of a hemispherical optic 22.

While the phosphor 14, glass cover 18, and optic 22 are generally illustrated and explained with a hemispherical shape, the shape should not be considered so limited. That is, the shape can include hemispheres (see FIG. 1), ellipsoids, spheres 24 (see FIG. 3), or other similar shapes as is desired or necessary. In this way, the phosphor 26, glass cover 28, and optic 30 will include an opening 34 for electrical connections 36 and support 38 to the LED source 32. While not necessary, the opening 34 should be small in construction to further minimize emission losses.

In optimizing η_(q) of Equation 1 and the ELIXIR LED 10 of FIG. 1, the phosphor 14 and glass cover 18 are replaced with a light emitting composite material of FIG. 4. The light emitting composite material 40 integrates the first and second non-planar layers as an inorganic crystalline 42 suspended in a glassy material 44 matrix as illustrated in FIG. 4. The inorganic crystalline 42 and glassy material 44 are selected such that, n_(c), the index of refraction of the inorganic crystalline 42 is approximately equal, n_(g), to the index of refraction of the glassy material 44. The result is a nearly index-matched luminescent glass-crystal composite (NIMLGCC) 40 that maximizes the quantum efficiency of the phosphor by reducing, or eliminating, optical scattering.

Because of their large surface-to-volume ratio, nanoparticles have low quantum efficiencies. Thus, the inorganic crystalline 42 should be a particle 46 that is larger than about 10 nm, i.e. not a nanoparticle. However, because the light-emitting composite material 40 has a finite thickness, the inorganic crystalline 42 should be smaller than the thickness of the light-emitting composite material 40. Suitable inorganic crystalline 42 can include Y_(x)Gd_(y)Al_(v)Ga_(w)O₁₂:M³⁺, wherein x+y=3 and v+w=5; SrGa₂S₄:M²⁺; SrS:M²⁺; X₂Si₅N₈:M²⁺; and XSi₂O₂N₂:M²⁺, wherein X is selected from a group consisting of Be, Mg, Ca, Sr, and Ba and wherein M is selected from a group consisting of Ce, Eu, Mn, Nd, Pr, Sm, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Sc, Ti, V, Cr, Fe, Co, Ni, Cu, Zn, Ir, and Pt.

It would be permissible for the light-emitting composite material 40 to comprise a combination of different inorganic crystallines 42 to obtain a color mixing result of broadband white light emission. For example, two or more UV- or violet-short wavelength inorganic crystalline materials 42 in the 350 nm to 430 nm range will absorb the first wavelength from the LED source 12 and reemit a combination of red, green, and blue light to achieve a broadband white. The broadband white resulting from a color-mixing light-emitting composite 40 is more highly uniform as compared to conventional phosphor color mixing because the emissions of red, green, and blue originate from the same location. In another example, where blue or blue-green short wavelength LED sources 12 are used (430 nm to 500 nm), these inorganic crystalline materials 42 will reemit the first wavelength in combination with red and green light to achieve a broadband white.

The glassy material 44 in which the inorganic crystalline material is suspended can include an optical glass or other glass material, such as those manufactured by Schott North America (Elmsford, N.Y.) including SF-57, SF-67, LASF-9, LASF047, SK-57, PK-51, PK-53, FK-51A, and FK-5. Other optical glasses can include those according to the teachings of U.S. Appl. No. 2005/0075234 or U.S. Pat. No. 3,960,579, which are hereby incorporated by reference, in their entirety.

The glassy material 44 can comprise about 10% to about 99.9% of the light-emitting composite material 40 by weight.

As indicated above, the selection of an inorganic crystalline 42 and glassy material 44 should be according to index-matching. That is, the index of refraction, n_(c), of the inorganic crystalline 42 should be approximately equal to the index of refraction, n_(g), of the glassy material to provide an index of refraction, n₂, for the light-emitting composite material 40.

By nearly index-matching the inorganic crystalline 42 to the glassy material 44, scattering induced loss is nearly eliminated. That is, by establishing an n_(g) that is approximately equal to n_(c), the phosphor-emission will travel at a speed within the inorganic crystalline 42 that is approximately equal to the travel speed within the glassy material 44 and thus reduce refraction, or a change in the direction of the emission. As a result, scattering is reduced and η_(p) increased.

Total internal reflections occur when the interface between first and second material 52, 54 cannot be traversed by light, as illustrated with a conventional LED device 50 in FIG. 5A. This condition at the interface occurs when the refractive index of the first material 52 (here the phosphor) is greater than the refractive index of the second material 54. According to Snell's Law, the light cannot traverse the interface, but will either refract along the interface or undergo total internal reflection. Total internal reflection of the emission 58 continues until all of the energy in the emission is reabsorbed 60 by the phosphor.

FIG. 5B shows a hemispherical optic 22 having an internal radius, r, and an outer radius, R. Here, phosphor 14 (which includes, e.g., the light-emitting composite material 40) is located at the internal radius r of the optic 22. Ideally, the optic 22 is constructed from the same transparent material as a host material of the phosphor 14 (e.g., the host material 44 of the light-emitting composite material 40.) In this manner, a refractive index n₂ of the optic 22 is equal to or larger than the refractive index of the phosphor 14. A refractive index of the medium that surrounds the optic 22 is n₁. Snell's Law can be used to calculate a configuration of the optic 22 for which total internal reflections are eliminated inside the optic 22. This configuration is determinable by establishing a ratio of a radius to the phosphor 14 (which includes, e.g., the light-emitting composite material 40), r, to a radius to the outer diameter of the optic 22, R. This ratio of radii must be less than or equal to the ratio of the index of refraction for material external to the optic 22 (and, hence, external to the ELIXIR LED device 10), n₁, and n₂: r/R≦n ₁ /n ₂  Equation 3 Often, this material external to the ELIXIR LED 10 will be air, or vacuum, having n₁=1. Thus, total internal reflection inside the optic 22 will be avoided when r/R is less than the inverse of n₂.

The ELIXIR LED 10 of FIG. 9 includes a planar reflector 16, an LED source 12 protruding through the planar reflector 16, a phosphor 14—in this case including the light-emitting composite material 40—and an optic 22. The phosphor 14 is spaced apart from the LED source 12, such that an enclosure formed by the phosphor 14 and the planar reflector 16 encloses the LED source 12. In this case, a medium inside the enclosure is air, with refractive index n=1. The phosphor 14 and the optic 22 are coupled together and positioned upon the planar reflector 16 as provided by Equation 3. Materials for the planar reflector 16 can include aluminized Mylar attached to an acrylic sheet or a 3M Vikuiti enhanced specular reflector film. By eliminating the reflector cup of conventional, LED package design, phosphor-emission can leave the ELIXIR LED 10 without being trapped between the planar reflector 16 and the phosphor 14.

Finally, the optic 22 positioned externally to the light-emitting composite material 40 can be constructed of a glass material similar to the glassy material 44 of the light-emitting composite material 40. Other materials can also be used so long as refractive index of the optic 22 is greater than or equal to n₂. Suitable materials for the optic 22 construction can be polymethyl methacrylate (PMMA), silicones, and glasses having refractive indices of about 1.3 to about 2.2.

When PMMA is used in constructing the optic 22, the method can include polymerization of a methyl methacrylate monomer around a 25 mL round bottom flask to form an inner radius of the optic 22 with an inner diameter of approximately 3.8 cm. The outer diameter of the optic 22 can be shaped, for example, by an aluminum mold. However, other fabrication methods would be known and the size could be varied according to a particular need.

The monomer for constructing the optic 22 can be purified to eliminate contaminants. For PMMA, the methyl methacrylate monomer can be washed with a solution of sodium hydroxide, rinsed with deionized water, and dried with anhydrous magnesium sulfate. Polymerization can be initiated by benzoyl peroxide and heating the solution to 90° C. The resultant viscous solution is then poured into a mold, such as the one described previously, and then cured in an oven at 35° C. for one week.

The optic 22 could also be produced with a high quality injection molding of PMMA rather than polymerization.

While the ELIXIR LED 10 of FIG. 9 is generally shown to include an air gap 62, it would be understood that the air gap 62 can be partially, or completely, replaced with a glass or polymer having an refractive index less than or equal to n₂.

In other embodiments, the NIMLGCC can be used with visible diode-pumped solid-state lasers 84 as illustrated in FIG. 7. Conventional diode-pumped solid-state lasers 64 (see FIG. 6) include a light source 66 comprising a power source 68 providing energy to a diode pump 70, such as AlGaAs laser diode. Photons emitted from the diode pump 70 are directed into a laser cavity 74 by a fiber 72. The photons entering the laser cavity 74 are directed to a population inversion crystal 76, such as a YAG:Nd, which when excited by the photons will emit a light at a first wavelength (at 1064 nm). Light of this first wavelength can then reflect between input and output mirrors 78, 80 and yield a coherent emission, characteristic of the solid-state laser 64. A portion of the first wavelength will impact a doubling crystal 82, such as a potassium titanium oxide phosphate (KTP) crystal, which doubles the frequency of the light (conversion of the first wavelength to a second wavelength equal to 532 nm). Light of the second wavelength is not reflected by the output mirror 80, but rather passes through the output mirror 80 as the laser output.

However, the YAG:Nd population inversion crystal 76 and KTP doubling crystal 82 are a highly expensive component of the conventional pumped solid-state laser 64. The NIMLGCC, as explained above, can provide an economical and energetically efficient alternative to the conventional pumped solid-state laser 64.

For example, as in FIG. 7, the YAG:Nd population inversion crystal 76 and NTP doubling crystal 82 are replaced by an NIMLGCC crystal 86 in the pumped solid-state laser 84 according to the present invention. The NIMLGCC crystal 86 can be constructed in a manner as described above and is generally molded and polished to a typical optics standard. In this way, a first wavelength, such as from a 405 nm emitting Indium Gallium Nitride (InGaN) diode 88 of the light source 67, reflects between the input and output mirrors 78, 80 as a coherent emission within laser cavity 75. At least a portion of this first wavelength can be absorbed by the NIMLGCC crystal 86 and a second wavelength is emitted. This second wavelength will traverse the output mirror 80 and will be emitted as the laser output.

In yet another embodiment, the NIMLGCC can be used as a luminescence collector 90 for energy conversion, as shown in FIG. 8. Therein, the NIMLGCC is molded into a sheet acting as a light tube 92. As a light tube 92, the phosphor emissions 94 will be contained as total internal reflections 96, which are directed toward first and second ends 98, 100 of the light tube 92. Total internal reflection 96 is accomplished by the selection of an NIMLGCC material for the light tube 92 in accordance with Snell's law and as described previously. Thus, the NIMLGCC material should be selected so as to maximize the total internal reflections 96 from the phosphor emissions 94 while minimizing transmitted light 102.

In operation of the light tube 92, a light source 104 emits a first wavelength incident 106 to the light tube 92. The first wavelength is absorbed by an inorganic crystalline 42 within the NIMLGCC light tube 92 and reemitted at a second wavelength. This second wavelength is transmitted through the light tube 92 by total internal reflection 96 to the first or second ends 98, 100 of the light tube 92. As the second wavelength leaves the light tube 92 at the first or second ends 98, 100 as reflected light 108, the reflected light 108 impacts a photovoltaic cell 110. The photovoltaic cell 110 collects a substantial portion of the reflected light 108 and converts the reflected light 108 into another energy, such as electrical current.

The light tube 92 can be constructed with a small edge profile, which enables the use of a relatively small photovoltaic cell 110. Thus, the first and second ends 98, 100 of the light tube 92 are approximately similar in size to the surface area of the photovoltaic cell 110. This allows for increased likelihood that the reflected light 108 will impact the photovoltaic cell 110.

Suitable materials for the photovoltaic cell are known, but can generally include Si, Ge, GaAs, AlAs, InAs, AlP, InP, GaP, ZnSe, or CdSe, or combinations thereof.

EXAMPLE 1

The efficiency of the ELIXIR LED 10 according to the present invention is demonstrated with a computer simulation of a ray tracing diagram, shown in FIG. 9. Herein, the ELIXIR LED 10 is constructed as described above with a phosphor radius, r, and equal to 1.9 cm.

The ray tracing diagram illustrates the various paths the phosphor-emitting photons can take in exiting the ELIXIR LED 10. Ray 1 exits the ELIXIR LED 10 without encountering any reflections and comprises approximately 35% of the phosphor-emissions, Ray 2 (representing approximately 35% of the phosphor-emission) demonstrates one particular benefit of the ELIXIR LED 10. Ray 2 is emitted in a direction toward the planar reflector 16, where substantial emissions loss occurs in a conventional pcLED package design. However, in the ELIXIR LED 10, the phosphor emission is reflected at the phosphor-air interface 112. Ray 2 can then exit the ELIXIR LED 10 and may avoid the planar reflector 16 entirely. Ray 3, comprising approximately 17% of the phosphor-emission, heads directly to the reflector 16 before exiting the ELIXIR LED 10 and never encounters the phosphor-air interface 112. Ray 4 is transmitted across the phosphor-air interface 112 but avoids the LED source 12 and recrosses the phosphor-air interface 112 before exiting the ELIXIR LED 10. The transmissions represented by Ray 4 account for approximately 13% of the total phosphor emissions. Finally, Ray 5 is transmitted across the phosphor-air interface 112 and enters the LED source 12 where the highest losses would occur within conventional LED package designs. In the ELIXIR LED 10 constructed with a radius of the phosphor 14, Ray 5 comprises less than 0.1% of the total phosphor-emission.

While the invention has been illustrated by a description of various embodiments and while these embodiments have been described in considerable detail, it is not the intention of the applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art. Thus, the invention in its broader aspects is therefore not limited to the specific details, representative apparatus and method, and illustrative example shown and described. Accordingly, departures may be made from such details without departing from the spirit or scope of applicants' general inventive concept. 

What is claimed is:
 1. A light emitting device, comprising: a base; a light emitting diode supported by the base; a first layer spaced apart from the light emitting diode and comprising a light emitting material, the first layer having a refractive index n_(first) _(—) _(layer), wherein a gap between the light emitting diode and the first layer has a refractive index n_(gap) that is less than n_(first) _(—) _(layer), and a transparent optic having a refractive index n_(optic) that is greater than or equal to n_(first) _(—) _(layer), wherein the transparent optic has a first convex surface facing away from the light emitting diode and having a first radius of curvature R, the first convex surface being a surface through which the light emitting device emits light into a medium adjacent the first convex surface, the medium having a refractive index n_(medium), and the first layer being positioned between the transparent optic and the light emitting diode, and a second convex surface in contact with the first layer and having a second radius of curvature r, wherein r/R is equal to n_(medium)/n_(optic).
 2. The light emitting device of claim 1, wherein the first layer is a non-planar layer.
 3. The light emitting device of claim 1, wherein the first layer has the radius of curvature r.
 4. The light emitting device of claim 1, wherein the first layer comprises a concave surface facing the light emitting diode.
 5. The light emitting device of claim 1, wherein the first layer has a hemispherical, ellipsoidal, or spherical shape.
 6. The light emitting device of claim 1, wherein the light emitting material is a composite material.
 7. The light emitting device of claim 6, wherein the composite material comprises an inorganic crystalline material suspended in a glassy material.
 8. The light emitting device of claim 1, wherein the light emitting material comprises a phosphor.
 9. The light emitting device of claim 1, wherein the first layer comprises a phosphor and a polymer, a silicone, or a glass.
 10. The light emitting device of claim 1, wherein the light emitting diode and light emitting material are selected so that the light emitting device has a broadband white emission spectrum.
 11. The light emitting device of claim 1, wherein the first convex surface has a hemispherical, ellipsoidal, or spherical shape.
 12. The light emitting device of claim 1, wherein n_(optic) is in a range from about 1.3 to about 2.2.
 13. The light emitting device of claim 1, further comprising a reflector extending between the light emitting diode and the first layer.
 14. The light emitting device of claim 13, wherein the reflector extends adjacent the first layer and the transparent optic.
 15. The light emitting device of claim 13, wherein the reflector is a planar reflector.
 16. The light emitting device of claim 1, wherein the gap is an air gap.
 17. A light emitting device, comprising: a base; a light emitting diode supported by the base; a first layer spaced apart from the light emitting diode and comprising a light emitting material, the first layer having a refractive index n_(first) _(—) _(layer), wherein an air gap is enclosed between the light emitting diode and the first layer; and a transparent optic having a refractive index n_(optic) that is in a range from about 1.3 to about 2.2, the transparent optic having a first curved surface facing away from the light emitting diode, the first curved surface being a surface through which the light emitting device emits light into a medium adjacent the first curved surface, the medium having a refractive index n_(medium), and the first layer being positioned between the transparent optic and the light emitting diode, the curved surface having a first radius of curvature R, and a second curved surface in contact with the first layer and having a second radius of curvature r, where r/R is equal to n_(medium)/n_(optic). 